Publication

Abstract : The exploration of ternary nanofluid (T-NF) movement through a diverging channel has important real-world applications. One such application is thermal management systems, where monitoring and improving heat movement is critical. As a result, the current study evaluates the thermal transfer of T-NF movement over a divergent channel while accounting for the magnetic field, thermal radiation, and porous surface. In this problem, T-NF is generated by considering CoFe2O4, Fe3O4 and ZnO as nanoparticles dispersed in 50% of EG+H2O base fluid. Ordinary differential equations (ODEs) are generated from the governing modeled equations, and a statistical approach is used to find solutions. The important dimensionless constraints are listed, and their effects on different profiles are explored. The results show that the skin friction coefficient is typically lower in a suction scenario and decreases as the magnetic field and solid volume fractions are enhanced.